Raloxifene preserves phenytoin and sodium valproate induced bone loss by modulating serum estradiol and TGF-β3 content in bone of female mice

• Chronic treatment with phenytoin and valproate induces bone loss in Swiss albino female mice.
• Bone loss is accompanied by estrogen depletion and reduced TGFβ3 in lumbar bones.
• Raloxifene prevents and ameliorates bone loss by restoring serum estradiol and TGFβ3 content of bone.
• There is no interaction of raloxifene with these antiepileptic drugs at pharmacodynamics level.

Antiepileptic drugs (AEDs)-induced adverse consequences on bone are now well recognized. Despite this, there is limited data on the effect of anti-osteoporotic therapies on AEDs-induced bone loss. We hypothesize that estrogen deprivation following phenytoin (PHT) and sodium valproate (SVP) therapy could lead to adverse bony effects. Both PHT and SVP inhibit human aromatase enzyme and stimulate microsomal catabolism of oestrogens. Estrogen deficiency states are known to reduce the deposition of transforming growth factor-β (TGF-β3), a bone matrix protein, having anti-osteoclastic property. Thus, an attempt was made to investigate the effect of raloxifene, a selective oestrogen receptor modulator, in comparison with calcium and vitamin D3 (CVD) supplementation, on PHT and SVP-induced alterations in bone in mice and to unravel the role of estradiol and TGF-β3 in mediation of bony effects by either AEDs or raloxifene. Further, the effect of raloxifene on seizures and on the antiepileptic efficacy of PHT and SVP was investigated. Swiss strains of female mice were treated with PHT (35 mg/kg, p.o.) and SVP (300 mg/kg, p.o.) for 120 days to induce bone loss as evidenced by reduced bone mineral density (BMD) and altered bone turnover markers (BTMs) in lumbar bones (alkaline phosphatase, tartarate resistant acid phosphatase, hydroxyproline) and urine (calcium). The bone loss was accompanied by reduced serum estradiol levels and bone TGF-β3 content. Preventive and therapeutic treatment with raloxifene ameliorated bony alterations and was more effective than CVD. It also significantly restored estradiol and TGF-β3 levels. Deprived estrogen levels (that in turn reduced lumbar TGF-β3 content) following PHT and SVP, thus, might represent one of the various mechanisms of AEDs-induced bone loss. Raloxifene preserved the bony changes without interfering with antiepileptic efficacy of these drugs, and hence raloxifene could be a potential therapeutic option in the management of PHT and SVP-induced bone disease if clinically approved.

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